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224 lines
6.3 KiB
C++
224 lines
6.3 KiB
C++
//
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// DiskController.cpp
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// Clock Signal
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//
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// Created by Thomas Harte on 14/07/2016.
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// Copyright © 2016 Thomas Harte. All rights reserved.
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//
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#include "DiskController.hpp"
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#include "../../NumberTheory/Factors.hpp"
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using namespace Storage::Disk;
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Controller::Controller(int clock_rate, int clock_rate_multiplier, int revolutions_per_minute) :
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clock_rate_(clock_rate * clock_rate_multiplier),
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clock_rate_multiplier_(clock_rate_multiplier),
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rotational_multiplier_(60, revolutions_per_minute),
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cycles_since_index_hole_(0),
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motor_is_on_(false),
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is_reading_(true),
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TimedEventLoop((unsigned int)(clock_rate * clock_rate_multiplier)) {
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// seed this class with a PLL, any PLL, so that it's safe to assume non-nullptr later
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Time one(1);
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set_expected_bit_length(one);
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}
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void Controller::setup_track() {
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track_ = drive_->get_track();
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Time offset;
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Time track_time_now = get_time_into_track();
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if(track_) {
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Time time_found = track_->seek_to(track_time_now);
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offset = track_time_now - time_found;
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}
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get_next_event(offset);
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}
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void Controller::run_for(const Cycles &cycles) {
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Time zero(0);
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if(drive_ && drive_->has_disk() && motor_is_on_) {
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if(!track_) setup_track();
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int number_of_cycles = clock_rate_multiplier_ * cycles.as_int();
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while(number_of_cycles) {
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int cycles_until_next_event = (int)get_cycles_until_next_event();
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int cycles_to_run_for = std::min(cycles_until_next_event, number_of_cycles);
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if(!is_reading_ && cycles_until_bits_written_ > zero) {
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int write_cycles_target = (int)cycles_until_bits_written_.get_unsigned_int();
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if(cycles_until_bits_written_.length % cycles_until_bits_written_.clock_rate) write_cycles_target++;
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cycles_to_run_for = std::min(cycles_to_run_for, write_cycles_target);
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}
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cycles_since_index_hole_ += (unsigned int)cycles_to_run_for;
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number_of_cycles -= cycles_to_run_for;
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if(is_reading_) {
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pll_->run_for(Cycles(cycles_to_run_for));
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} else {
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if(cycles_until_bits_written_ > zero) {
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Storage::Time cycles_to_run_for_time(cycles_to_run_for);
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if(cycles_until_bits_written_ <= cycles_to_run_for_time) {
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process_write_completed();
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if(cycles_until_bits_written_ <= cycles_to_run_for_time)
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cycles_until_bits_written_.set_zero();
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else
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cycles_until_bits_written_ -= cycles_to_run_for_time;
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} else {
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cycles_until_bits_written_ -= cycles_to_run_for_time;
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}
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}
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}
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TimedEventLoop::run_for(Cycles(cycles_to_run_for));
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}
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}
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}
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#pragma mark - Track timed event loop
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void Controller::get_next_event(const Time &duration_already_passed) {
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if(track_) {
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current_event_ = track_->get_next_event();
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} else {
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current_event_.length.length = 1;
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current_event_.length.clock_rate = 1;
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current_event_.type = Track::Event::IndexHole;
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}
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// divide interval, which is in terms of a single rotation of the disk, by rotation speed to
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// convert it into revolutions per second; this is achieved by multiplying by rotational_multiplier_
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set_next_event_time_interval((current_event_.length - duration_already_passed) * rotational_multiplier_);
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}
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void Controller::process_next_event()
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{
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switch(current_event_.type) {
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case Track::Event::FluxTransition:
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if(is_reading_) pll_->add_pulse();
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break;
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case Track::Event::IndexHole:
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printf("%p %d [/%d = %d]\n", this, cycles_since_index_hole_, clock_rate_multiplier_, cycles_since_index_hole_ / clock_rate_multiplier_);
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cycles_since_index_hole_ = 0;
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process_index_hole();
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break;
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}
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get_next_event(Time(0));
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}
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Storage::Time Controller::get_time_into_track() {
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// this is proportion of a second
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Time result(cycles_since_index_hole_, 8000000 * clock_rate_multiplier_);
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result /= rotational_multiplier_;
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result.simplify();
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return result;
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}
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#pragma mark - Writing
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void Controller::begin_writing() {
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is_reading_ = false;
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write_segment_.length_of_a_bit = bit_length_ / rotational_multiplier_;
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write_segment_.data.clear();
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write_segment_.number_of_bits = 0;
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write_start_time_ = get_time_into_track();
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}
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void Controller::write_bit(bool value) {
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bool needs_new_byte = !(write_segment_.number_of_bits&7);
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if(needs_new_byte) write_segment_.data.push_back(0);
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if(value) write_segment_.data[write_segment_.number_of_bits >> 3] |= 0x80 >> (write_segment_.number_of_bits & 7);
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write_segment_.number_of_bits++;
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cycles_until_bits_written_ += cycles_per_bit_;
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}
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void Controller::end_writing() {
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is_reading_ = true;
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if(!patched_track_) {
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// Avoid creating a new patched track if this one is already patched
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patched_track_ = std::dynamic_pointer_cast<PCMPatchedTrack>(track_);
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if(!patched_track_) {
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patched_track_.reset(new PCMPatchedTrack(track_));
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}
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}
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patched_track_->add_segment(write_start_time_, write_segment_);
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invalidate_track(); // TEMPORARY: to force a seek
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}
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#pragma mark - PLL control and delegate
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void Controller::set_expected_bit_length(Time bit_length) {
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bit_length_ = bit_length;
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bit_length_.simplify();
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cycles_per_bit_ = Storage::Time(clock_rate_) * bit_length;
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cycles_per_bit_.simplify();
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// this conversion doesn't need to be exact because there's a lot of variation to be taken
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// account of in rotation speed, air turbulence, etc, so a direct conversion will do
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int clocks_per_bit = (int)cycles_per_bit_.get_unsigned_int();
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pll_.reset(new DigitalPhaseLockedLoop(clocks_per_bit, 3));
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pll_->set_delegate(this);
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}
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void Controller::digital_phase_locked_loop_output_bit(int value) {
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process_input_bit(value, (unsigned int)cycles_since_index_hole_);
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}
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#pragma mark - Drive actions
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bool Controller::get_is_track_zero() {
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if(!drive_) return false;
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return drive_->get_is_track_zero();
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}
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bool Controller::get_drive_is_ready() {
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if(!drive_) return false;
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return drive_->has_disk();
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}
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bool Controller::get_drive_is_read_only() {
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if(!drive_) return false;
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return drive_->get_is_read_only();
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}
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void Controller::step(int direction) {
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invalidate_track();
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if(drive_) drive_->step(direction);
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}
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void Controller::set_motor_on(bool motor_on) {
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motor_is_on_ = motor_on;
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}
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bool Controller::get_motor_on() {
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return motor_is_on_;
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}
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void Controller::set_drive(std::shared_ptr<Drive> drive) {
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if(drive_ != drive)
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{
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invalidate_track();
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drive_ = drive;
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}
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}
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void Controller::invalidate_track() {
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track_ = nullptr;
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if(patched_track_) {
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drive_->set_track(patched_track_);
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patched_track_ = nullptr;
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}
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}
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void Controller::process_write_completed() {}
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